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Rapid visual screening of different housing typologies in Himachal
Pradesh, India
by
Ajay Kumar Sreerama, Chenna Rajaram, Shashank Mishra, Pradeep Kumar Ramancharla, Anoop Karnath
in
Natural Hazards
Report No: IIIT/TR/2017/-1
Centre for Earthquake EngineeringInternational Institute of Information Technology
Hyderabad - 500 032, INDIAFebruary 2017
ORIGINAL PAPER
Rapid visual screening of different housing typologiesin Himachal Pradesh, India
Sreerama Ajay Kumar1 • Chenna Rajaram1• Shashank Mishra2 •
Ramancharla Pradeep Kumar1 • Anoop Karnath2
Received: 10 December 2015 / Accepted: 2 November 2016� Springer Science+Business Media Dordrecht 2016
Abstract Methods capable of assessing the vulnerability of houses for future earthquakes
are of fundamental importance for the safety and development of an area. As the detailed
assessment is limited to number of houses and cost, one of the appraising methods cur-
rently used for seismic vulnerability assessment is rapid visual screening (RVS). This
methodology has led to determination of risk of an area subjected to an earthquake event.
Many codes have limited rapid visual screening to housing typologies like reinforced
concrete and Brick masonry structures. This paper delivers an approach on how to perform
RVS for five varieties of buildings in Himachal Pradesh state. The RVS scores have been
calculated for 9099 buildings and normal distribution curves are plotted for each typology
of building to understand the distribution of buildings in Himachal Pradesh. Finally, a new
modified format for performing rapid visual screening has been proposed at the end.
Keywords Rapid visual screening � Housing � Normal distribution � Building typology
1 Introduction
Structural damages in buildings during an earthquake are accepted constructively by
majority of seismic codes in the world, given that there is no human loss. Undeniably many
such damages have occurred due to earthquakes in the past. Many new constructions were
unaffected by the improvements of codes, but the earthquake safety of existing buildings is
& Chenna Rajaramrajaram.chenna@research.iiit.ac.in
& Ramancharla Pradeep Kumarramancharla@iiit.ac.in
1 Civil Engineering, Earthquake Engineering Research Centre, International Institute of InformationTechnology, Hyderabad 500 032, India
2 Taru Edge Leading Private Limited, New Delhi 110016, India
123
Nat HazardsDOI 10.1007/s11069-016-2668-3
under question. In case of Indian subcontinent, it faces serious earthquake threat due to
rapid growth of urban population, wherein nearly 60% of landmass in India is part of
moderate-to-severe earthquake prone area. However, over 80% of population is living in
this 60% of the land (Pradeep and Murty 2014). In last decade, India has witnessed
earthquakes like that of 2001 Bhuj earthquake of M7.7, 2004 Sumatra earthquake of M9.3,
2005 Kashmir earthquake of M7.6, 2009 Andaman Islands of M7.5, and 2011 Sikkim
earthquake of M6.8, etc. and an overall of 24 moderate to severe earthquakes were
experienced, where around 4.25 lakh casualties and property loss was caused (Ref.
Table 1). However, similar intensity earthquakes in the US, Japan, etc., did not lead to such
an enormous loss of lives, as the structures in these countries are earthquake resistant
(NDMA Guidelines 2007). During the 2001 Bhuj earthquake, numerous recently built
Reinforced Concrete (RC) structures collapsed in Gandidham and Bhuj areas in Gujarat
(EERI Earthquake Report 2001; Murty et al. 2002). In 2005 Kashmir earthquake, signif-
icant damage was attributed for stone masonry buildings, particularly random rubble type
structures, which are poor seismic performance (EERI Earthquake Report, 2005). Most of
the multi storey RC buildings were non-engineered and sustained considerable damage
during the 2011 Sikkim earthquake (EERI Earthquake Report 2012). So, these failures
Table 1 Major earthquake in India. Source: Indian Meteorological Department, IMD
S. no. Date Epicenter Location Mw Casualties
1 1818 Jun 16 (23.60, 68.60) Kutch, Gujarat 8.0 2000
2 1869 Jan 10 (25.00, 93.00) Nearcachar, Assam 7.5 Unknown
3 1885 May 30 (34.10, 74.60) Sopor, J&K 7.0 Unknown
4 1897 Jun 12 (26.00, 91.00) Shillong plateau 8.7 1500
5 1905 Apr 04 (32.30, 76.30) Kangra, HP 8.0 19,000
6 1918 Jul 08 (24.50, 91.00) Srimangal, Assam 7.6 Unknown
7 1930 Jul 02 (25.80, 90.20) Dhubri, Assam 7.1 Unknown
8 1934 Jan 15 (26.60, 86.80) Bihar–Nepal border 8.3 10,700
9 1943 Oct 23 (26.80, 94.00) Assam 7.2 Unknown
10 1950 Aug 15 (28.50, 96.70) Arunachal Pradesh–China Border 8.5 1526
11 1956 Jul 21 (23.30, 70.00) Anjar, Gujarat 7.0 Unknown
12 1967 Dec 10 (17.37, 73.75) Koyna, Maharashtra 6.5 177
13 1975 Jan 19 (32.38, 78.49) Kinnaur, HP 6.2 Unknown
14 1988 Aug 06 (25.13, 95.15) Manipur–Myanmar border 6.6 1000
15 1988 Aug 21 (26.72, 86.63) Bihar–Nepal border 6.4 1004
16 1991 Oct 20 (30.75, 78.86) Uttarkashi, UP 6.6 2000
17 1993 Sep 30 (18.07, 76.62) Latur-Osmanabad, Maharashtra 6.3 9748
18 1997 May 22 (23.08, 80.06) Jabalpur,MP 6.0 38
19 1999 Mar 29 (30.41, 79.42) Chamoli Dist, UP 6.8 100
20 2001 Jan 26 (23.40, 70.28) Bhuj, Gujarat 7.7 20,023
21 2004 Dec 26 (03.34, 96.13) Off West Coast of Sumatra 9.3 283,106
22 2005 Oct 08 (34.48, 73.61) Kashmir 7.6 74,500
23 2009 Aug 10 (14.01, 92.92) Andaman Islands, India region 7.5 Unknown
24 2011 Sep 18 (27.7, 88.2) Sikkim Nepal border 6.8 Unknown
Nat Hazards
123
project the urgent need to perform the seismic vulnerability assessment of buildings and
suggest possible solutions to retrofit them. Since the detailed assessment of buildings is a
complex and expensive task, it cannot be performed on all the buildings in an area. Past
reconnaissance survey reports suggest that a simple assessment of existing buildings is
necessarily required. Most of the methods follow a three level assessment procedure,
namely:
(a) Phase-I: Rapid visual screening (RVS).
(b) Phase-II: Preliminary assessment.
(c) Phase-III: Detailed evaluation.
The RVS methodology is referred to as a ‘‘sidewalk survey’’ in which an experienced
screener visually examines a building to identify features such as the building type, seismic
zone, soil conditions, horizontal and vertical irregularities, apparent quality in buildings
and short column etc. that affect the seismic performance of the building. This side walk
survey is carried out based on the checklists provided in a proforma for all five typologies
of the buildings. Other important data regarding the building including the occupancy of
the building and the presence of nonstructural falling hazards is also gathered during the
screening. A performance score or RVS corresponding to these features is calculated for
the building based on numerical values on the RVS form. The performance score is
compared to a ‘‘cut-off’’ score to determine whether a building has potential vulnerability
and whether it should be further evaluated by an experienced engineer. The worldwide
practices on RVS are as follows.
A number of guidelines were developed by the Federal Emergency Management
Agency (FEMA) in the USA for seismic risk assessment and rehabilitation of buildings.
The RVS method was originally developed by the Applied Technology Council (ATC) in
the late 1980s and published in the FEMA: 154 in 1988. Later, it was developed in FEMA:
178-1989, 1992 (revised), FEMA: 310-1998 developed as revised version of FEMA:
178-1992, and FEMA: 154-1988, 2002 (revised), for rapid visual screening of buildings. A
different RVS procedure was developed based on fuzzy logic technique to categorize
buildings into five different damage grades (OASP 2000; Demartinos and Dristos 2006).
This technique was applied on 102 buildings, which were affected by 1999 Athens
earthquake. At the end, damage score was evaluated through a fuzzy inference system.
Another RVS method was suggested by National Research Council, Canada, which is
based on a seismic priority index. This method accounts for both structural and non-
structural factors including soil conditions, building occupancy, building importance,
falling hazards, occupied density and the duration of occupancy (NRCC 1993).
The Japanese procedure is based on seismic index (SI) for total earthquake resisting
capacity of a story which is estimated as the product of basic seismic index based on
strength and ductility indices, irregularity index and time index (TI). The evaluation is
based on few parameters and lacks clarity regarding the ranking of buildings based on a
scoring or rating system (JPDPA 2001). The New Zealand code recommends a two stage
seismic performance evaluation of buildings (NZSEE 2006). The Switzerland applies a
three stage concept for evaluating seismic risk. In first stage, seismic risk of a building is
roughly estimated and in second stage, seismic risk is studied in detailed. Strengthening
measures are employed in the last stage of seismic risk (SIA-2018 2004). The RVS method
developed was based on the ratio of roof displacement capacity to roof displacement
demand determined for life safety performance criteria and collapse prevention perfor-
mance criteria by Bogadici University and Istanbul Technical University. Later, this
method was improved on the basis of 454 reinforced concrete buildings surveyed after the
Nat Hazards
123
1999 Duzce earthquake and classified into four damage grades (Sen 2010; Hassan and
Sozen 1997; Ozdemir and Taskin 2006; Sucuoglu et al. 2007).
There have been some efforts in India towards developing RVS methods. Sinha and
Goyal (2004) have proposed a methodology for RVS of ten different types of buildings.
The procedure requires identification of the primary structural load carrying system and the
building attributes that are expected to modify the expected seismic performance for the
lateral load resisting system under consideration. A statistical analysis has been performed
to develop Expected Performance Score (EPS) for RC buildings based on the rapid visual
surveys in Ahmadabad, India (Jain et al. 2010; Keya 2008).
2 Vulnerability studies of cities
Vulnerability assessment of cities has been performed in the past based on population loss
estimation and estimation of direct and indirect losses due to various disasters. Some recent
vulnerability assessment studies are discussed in the following sections:
2.1 Tehran, Iran
Seismic vulnerability assessment was done in the city of Tehran based on buildings data
and damage for buildings for two earthquake scenarios (Nateghi 1998, 2000; Motamed and
Ashtiany 2012). Seismic building damage for earthquake scenarios was derived from
HAZUS software ranging from minor to major or complete damage (FEMA 1999; HAZUS
2000). Most of the buildings in the study area were found to be vulnerable considering the
two earthquake scenarios (South Ray Fault and Floating).
2.2 Dehradun, India
The vulnerability assessment in Uttaranchal was done by Singh (2005). This study
developed a methodology for loss estimation based on buildings and population loss.
A Geographic Information System based tool was developed for primarily population loss
estimation.
2.3 Kanpur, India
Preliminary evaluation was carried out on 30 multistoried RC buildings (IIT-GSDMA
Guidelines 2003). The study revealed that large openings, horizontal and vertical projec-
tions, presence of soft and weak stories and short column effects are major weaknesses in
the buildings at Kanpur from seismic safety point of view (Jain 2006).
2.4 Zeytinburnu, Turkey
This study is an implementation of the earthquake master plan for Istanbul metropolitan
area in the Zeytinburnu district with a population of 240,000 and more than 16,000
buildings (Ozcebe et al. 2006) as a part of seismic vulnerability of existing building, a
multi stage seismic safety assessment was performed by the Middle Eastern Technical
University (METU) in Ankara.
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2.5 Gandhidham, India
RVS was conducted on around 20,000 buildings in Gandhidham and Adipur cities (Sri-
kanth et al. 2010). Though there is a large variation in construction practices, about 26% of
buildings were RC buildings and 74% were of brick masonry. The study observes an RVS
score ranging from 60 to 120 both for masonry and concrete structures which reveals the
low quality of construction in this area (Srikanth et al. 2010).
2.6 Nanded, India
RVS was conducted on around 200 buildings in Nanded city. Initial observation reveals
that there are wide variety of construction practices; however, predominantly buildings are
classified as per material used, i.e., reinforced concrete, stone and brick masonry, tin shade
and other buildings, about 70.39% are reinforced concrete buildings, 25.79% are stone and
brick masonry, 2.54% are tin shade and 1.26% are other buildings. In RC buildings, score
was varying from 40 to 145 and for brick masonry building score was varying from 113 to
130. A detailed study has been done for buildings regarding the structural aspect and effect
of earthquakes (Narender 2014).
In the above literature, vulnerability studies of RC and brick masonry buildings have only
been considered.An attempt has beenmade to doRVS for five varieties of building in the state
of Himachal Pradesh. The state Himachal Pradesh consists of 1,027,788 buildings with RC,
brick masonry, stone masonry, rammed earth, and hybrid building typologies, having a
population of 6,856,509 in an area of 55,763 km2. For the purpose of study, 9099 buildings
were surveyed with the help of TARU Consultancy Private Limited. The above buildings
were selected based on the structural irregularity, terrain condition, construction year,
presence of cracks. Figure 1 shows the format of Building Vulnerability Assessment form
originally prepared byTARUconsultancy andHimachal Pradesh StateDisasterManagement
Authority (HPSDMA). The RVS scores are originally calculated using RVS forms of RC and
BrickMasonry. Later, these forms are modified for stonemasonry, rammed earth, and hybrid
buildings. Figure 2 represents a sample calculations of RVS score for five variety of build-
ings. As per statistics of surveyed buildings in Himachal Pradesh, around 17% (1541 out of
9099) of buildings are reinforced concrete, 48% (4363 out of 9099) of buildings are brick
masonry, 15% (1341 out of 9099) of buildings are stone masonry, 5% (518 out of 9099) of
buildings are rammed earth and 15% (1317 out of 9099) of buildings are hybrid. A schematic
diagram of assessment of a building is shown in Fig. 3. Present studymainly focuses on RVS
analysis of five varieties of buildings and the surveyed buildings distribution is shown in
Fig. 4. Preliminary and detailed analyses are beyond the scope of this paper.
3 Methodology
The evaluation is based on few parameters of building like building geometry, frame
action, hybrid action, pounding effect, structural irregularity, short columns, heavy over-
hangs, soil conditions, falling hazard, apparent building quality, diaphragm action etc. On
the basis of above-mentioned parameters, performance score of the buildings has been
calculated. The formula of the performance score (PS) is given in the following equation:
PS ¼ BSþX
½ðVSMÞ � ðVSÞ� ð1Þ
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where VSM represents the Vulnerability Score Modifiers and VS represents the Vulner-
ability Score that is multiplied with VSM to obtain the actual modifier to be applied to the
Basic Score (BS).
The RVS data of existing buildings in the region is plotted as Gaussian (Normal)
distribution. This distribution is commonly used for statistical analysis of large data. A
Fig. 1 Proposed format of building vulnerability assessment form prepared by TARU consultancy andHPSDMA
Nat Hazards
123
normal distribution in a variate X (RVS) with mean l and variance r is a statistical
distribution with probability density function is given in Eq. 2:
f ðxÞ ¼ 1
rffiffiffiffiffiffi2p
p e�ðx�lÞ
2r2 ð2Þ
Fig. 1 continued
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123
Generally, a cumulative probability refers to the probability that the value of a random
variable falls within a specified range (damage range based on design). Cumulative
probabilities refer to the probability that a random variable is less than or equal to a
specified value. The cumulative distribution function, which gives the probability that a
variate will assume a value Bx, is
DðxÞ ¼Zx
�1
f ðxÞdx ¼ 1
rffiffiffiffiffiffi2p
pZx
�1
e�ðx�lÞ=2r2dx ð3Þ
In RVS survey, even non-engineers may collect data and calculate RVS score for
buildings. Present study considers Himachal Pradesh as a case study to evaluate RVS score
for five varieties of buildings. The description of Himachal Pradesh is given in the fol-
lowing section.
4 A case study of Himachal Pradesh
Himachal Pradesh state is located 31.1033�N, 77.1722�E and lies in the Himalayan
Mountains, and is part of the Punjab Himalayas. Since the earthquake database in India is
still incomplete, especially regarding the earthquakes prior to the historical period (before
1800 A.D.), the largest instrumented earthquake in Himachal Pradesh was 1905 Kangra
earthquake (Mw7.8) (Ambraseys and Bilham 2000). The Himalayan Frontal Thrust, the
Main Boundary Thrust, the Krol, the Giri, Jutogh and Nahan thrusts lie in this region.
However, it must be stated that the proximity to faults does not necessarily translate into a
higher hazard as compared to areas located far away. As it is located on hilly terrain, land
Fig. 1 continued
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123
by its very nature is very fragile; therefore, threat due to earthquakes or landslides is high.
Hence, it has been considered as the apt study area. In total of 12 districts, Chamba, Kullu,
Kangra, Una, Hamirpur, Mandi, and Bilaspur districts lie in Zone V, whereas Lahul and
Fig. 2 Calculation of RVS score from RVS sheets for a reinforced concrete buildings, b brick masonrybuildings, c stone masonry buildings, d rammed earth buildings and e hybrid buildings
Nat Hazards
123
Spiti, Kinnaur, Simla, Solan and Sirmaur districts lie in Zone IV. The building’s data are
collected in every district of HP and procedure for data collection is described in the
following section.
Fig. 2 continued
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123
4.1 Data collection
An RVS format was developed for the android platform using ODK (Open Data Kit)
framework. After designing RVS format for android platform, it is stored on all the tablet
computers to be used for data collection. Once it is installed, it does not require Internet
connectivity to fetch the blank form. Data are collected from the field on day-to-day basis.
On a regular basis, surveyors were provided maps of the marked area along with the
number of buildings to be surveyed in that area. After filling all the required information in
the RVS format, latitude/longitude is recorded by enabling inbuilt GPS in the tablet
computer. Three photographs are taken for each building type in which first two pho-
tographs are taken as front and side elevation of the building and third photograph belongs
to any major building vulnerability feature. Data are sent to the server using Internet
connectivity. These data can be accessed from anywhere using the web application. Sur-
veyors sent the data every evening or next day (in case of non-availability of signal in the
remote area) after finishing the work.
Following were few challenges faced during the process of data collection.
1. More time was needed to reach the rural location due to limited travel connectivity.
2. It was difficult to get the information on few parameters such as horizontal bands in
the masonry buildings for well-plastered buildings.
3. Foundation details and age of construction was difficult to obtain, if the building was
not constructed by the owner.
Fig. 2 continued
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123
4.2 Housing potrayal
It has been observed that buildings in Himachal Pradesh are primarily classified into five
types viz., reinforced concrete buildings, brick masonry buildings, rammed earth buildings,
stone masonry and hybrid buildings from the surveyed buildings data. It also portrays
varied building construction methodologies in the state. From the surveyed buildings
database, it is categorized into three levels in the preliminary stage of analysis: (a) district
wise, (b) type of buildings and (c) building components. Following are few observations
from the database which explains the housing scenario in Himachal Pradesh.
1. Huge number of brick masonry buildings and wide variety of building construction are
present in Kangra district.
2. New construction of buildings has evolved in Kangra and Solan districts.
3. Presence of medium type of soil is more in every district except Kinnaur and Lahul
Spiti.
4. Existence of corner openings of buildings is more in Kangra and Solan districts and
substantial openings are more in Solan district.
5. Existence of horizontal bands of a building is more in Kangra district.
Fig. 3 Schematic diagram of assessment of a building
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6. Presence of soft story, heavy overhangs and short column is rare in most of the
districts.
7. Quality of construction is moderate in all districts of Himachal Pradesh.
8. Because of its geographical conditions, only few buildings are observed to be on the
flat ground, whereas large number of buildings is located on slopes.
The building parameters according to district are shown in Fig. 5. The primary
observation from housing classification is the complexity involved in construction of
buildings in the state.
4.3 RVS score calculation
Based on the factors given in the form, RVS scores have been calculated for the buildings
present in the database. The scores for RC, brick masonry, stone masonry, rammed earth
and hybrid buildings are 50–160; 40–220; 30–190; 50–160; and 60–140, respectively.
Normal distribution curves are generated for each district and building variety based on
RVS scores. District wise normal distribution curves for buildings are shown in Figs. 6, 7,
8, 9, 10 and 11.
Fig. 4 Location of buildings considered in RVS analysis
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1. The number of buildings surveyed in the districts of Bilaspur, Hamirpur, Kinnaur,
Kullu, Lahul Spiti, Shimla, Solan, Chamba, Kangra, Mandi, Sirmaur and Una are 383,
789, 149, 619, 70, 401, 1553, 513, 1929, 692, 585 and 637, respectively.
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
Brick MasonryHybrid
Rammed EarthRC Frame
Stone Masonry
0
500
1000
1500
Districts
Types of Construction
Types of Construction
No
of B
uild
ings
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
Not UndertakenUndertaken
0
1000
2000
Quality of Maintenance
DistrictsQuality of Maintenance
No
of B
uild
ings
UnaBilaspur
ChambaHamirpur
KangraKullu
MandiSimla
SirmurSolan
0-1010-20
20-3030-40
40-50>50
0
200
400
600
Districts
Age of Buildings
Age
No
of B
uild
ings
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
HardMedium
SoftNot Sure
0
1000
2000
Districts
Soil Types
Soil Types
No
of B
uild
ings
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
Does not ExistExists
0
1000
2000
Districts
Presence of Pounding
Presence of Pounding
No
of B
uild
ings
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
Does not ExistExists
Not Sure
0
500
1000
Districts
Corner Openings
Corner Openings
No
of B
uild
ings
UnaBilaspur
ChambaHamirpur
KangraKullu
MandiSimla
SirmurSolan
Does not ExistExists
Not Sure
0
500
1000
Districts
Substantial openings
Substantial openings
No
of B
uild
ings
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
Does not ExistExists
0
1000
2000
Diaphragm Openings
DistrictsDiaphragm Openings
No
of B
uild
ings
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
ExistsDoes not Exist
Not Sure
0
500
1000
Districts
Horizontal Bands
Horizontal Bands
No
of B
uild
ings
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
ExistsDoes not Exist
0
1000
2000
Soft Storey
DistrictsSoft Storey
No
of B
uild
ings
Fig. 5 Statistics of building parameters for 12 districts in HP state
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2. Around 62% of buildings were constructed majorly in last three decades, which
indicates the developmental growth of the state. The construction of buildings rapidly
increased during this period, especially in Kangra and Solan districts of HP. There
were few buildings that were constructed in 1970s. Most of the surveyed buildings are
single, two or three storied and a few are four and five storied. It is observed that the
quality of construction was moderate for 45% of RC buildings, 63% of brick masonry
buildings, 63% of stone masonry buildings, 60% of rammed earth, and 68% of hybrid
buildings. The quality of construction needs to be improved for hybrid, rammed earth
and stone masonry buildings. The construction practices are mostly done on hilly
terrain due to unavailability of space on flat terrain, and buildings are built in close
proximity to each other. Pounding effect was also observed for 55% of buildings.
3. Around 88% of RC buildings, 90% of brick masonry buildings, 80% of stone masonry
buildings, 86% of rammed earth, 82% of hybrid buildings are located on medium type
of soil. Around 10–15% of buildings are located on hard and soft soils. Buildings
located on soft soils are more vulnerable than medium soils and hard soils.
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
ExistsDoes not Exist
0
1000
2000
Heavy Overhangs
DistrictsHeavy Overhangs
No
of B
uild
ings
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
ExistsDoes not Exist
0
1000
2000
Short Column
DistrictsShort Column
No
of B
uild
ings
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
Flat to MildMedium
SteepNot Sure
0
1000
2000
Districts
Slope
Slope
No
of B
uild
ings
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUna
GoodModerate
Poor
0
500
1000
Districts
Quality of Construction
Quality of ConstructionN
o of
Bui
ldin
gs
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmur
SolanUnaHorizontal
VerticalDiagonalHorz & Diag
Horz & VertHorz, Vert & Diag
Vert & DiagNo Cracks
0
200
400
600
800
Districts
Types of Cracks
Types of Cracks
No
of B
uild
ings
Fig. 5 continued
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4. Presence of horizontal bands for buildings located in zone IV and V, increase the
seismic response of building. In the present survey only 32% of buildings are observed
to have bands.
5. Other parameters like openings, short column effect, slope angle heavy overhangs etc.
are classified district wise as shown in Fig. 5, but full access of the building is required
to get overview of it. The configuration of building is either rectangle, L-shape,
T-shape or U-shape for all types of buildings. It is one of the important virtues of
earthquake resistant buildings. For buildings, whose configuration is irregular, should
make it regular by providing expansion joints, so that, pounding effect due to
earthquake can be minimized in high seismic areas.
0 50 100 150 2000
50
100
150
200
RVS Score
No.
of R
C B
uild
ings
BilaspurChambaHamirpurKangraKulluLahulMandiShimlaSirmurSolanUna
Fig. 6 Normal distribution curves for RC buildings obtained from RVS score
0 50 100 150 200 2500
50
100
150
200
250
300
350
400
450
RVS Score
No.
of B
uild
ings
BilaspurChambaHamirpurKangraKulluMandiShimlaSirmurSolanUna
Fig. 7 Normal distribution curves for brick masonry buildings obtained from RVS score
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6. Many of the buildings use less than 230 mm as column size, which is not advisable in
seismic areas of zone IV and V. But, IS: 13920—2014 recommends that the minimum
size of column should be 300 mm. Around 63% of brick masonry buildings used
150–250 mm, 73% of hybrid buildings used 100–150 mm, 86% of RC buildings used
100–200 mm as column size.
20 40 60 80 100 120 140 160 1800
50
100
150
200
250
300
RVS Score
No
. of
Ram
med
Bu
ildin
gs
ChambaHamirpurKangraKulluMandiSirmurSolanUna
Fig. 9 Normal distribution curves for rammed earth buildings obtained from RVS score
0 50 100 150 2000
20
40
60
80
100
120
140
RVS Score
No
. of
Sto
ne
Bu
ildin
gs
BilaspurChambaHamirpurKangraKinnaurKulluLahulMandiShimlaSirmurSolanUna
Fig. 8 Normal distribution curves for stone masonry buildings obtained from RVS score
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4.4 Estimation of damage using RVS score
From literature, it is observed that the predominant RVS score lies in the range of 60–120
for both RC and brick masonry buildings in Gandhidham and Adipur cities in Gujarat
(Srikanth and Pradeep 2010; Srikanth et al. 2010). The mean and median values for both
RC and brick masonry buildings are 89.3, 90.0; 78.74, 80.0. Similarly, for Himachal
Pradesh, the RVS score lies in the range of 50–160 for reinforced concrete and 40–220 for
brick masonry buildings. For which the mean values for both RC and brick masonry
buildings are 106 and 120. The analysis was also carried out for stone masonry, rammed
earth and hybrid buildings. The RVS scores of five varieties of buildings were given in the
40 60 80 100 120 140 1600
50
100
150
200
250
RVS Score
No
. of
Hyb
rid
Bu
ildin
gs
BilaspurChambaHamirpurKangraKinnaurKulluLahulMandiShimlaSirmurSolanUna
Fig. 10 Normal distribution curves for hybrid buildings obtained from RVS score
40 60 80 100 120 140 160 180 2000
200
400
600
800
1000
1200
1400
1600
1800
RVS Score
No
. of
Bu
ildin
gs
RCBrickStoneRammedHybrid
Fig. 11 Normal distribution curves as per building variety
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earlier section. The mean values are slightly shifted towards right when compared to that of
study done in Gandhidham and Adipur cities. It is difficult to set a benchmark for RVS
score to understand the damage state of building. A normal distribution curves have been
drawn for RC, Brick Masonry, Stone Masonry, Rammed Earth and Hybrid type of buid-
lings are shown in Figs. 12–16 respectively. Also, all type of buildings is represented in
single plot and is shown in Fig. 17. For this purpose, damage is classified as no damage,
slight, moderate, severe and collapse based on l - 2r, l - 1r, l, l ? 1r, and l ? 2r.The mean and standard deviation of all building typologies are represented in Table 2. A
40 60 80 100 120 140 1600
1
2
3
4
5
6x 10
4
RVS Score
No
. of
RC
Bu
ildin
gs
BilaspurChambaHamirpurKangraKulluLahulMandiShimlaSirmurSolanUna
Fig. 12 Normal distribution curve for RC buildings
40 60 80 100 120 140 160 180 200 2200
1
2
3
4
5
6
7
8x 10
4
RVS Score
No
. of
Bri
ck B
uild
ing
s
BilaspurChambaHamirpurKangraKulluMandiShimlaSirmurSolanUna
Fig. 13 Normal distribution curve for brick masonry buildings
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representative diagram is shown in Fig. 18. Mean and standard deviations are calculated
for each type of building and the state of damage is estimated. Table 3 represents damage
state of five types of buildings and Fig. 18 shows the classification of damage of buildings
in Himachal Pradesh State.
The distribution of number of buildings in each district of HP with respect to RVS score
is shown in Fig. 19. The buildings whose RVS score lies between 130 and 150 are more in
number in all Mandi and Sirmaur districts and RVS score lies between 105 and 110 in
other districts. These buildings will suffer moderate damage as per damage classification
shown in Fig. 18. It means moderate damage buildings are sparsely distributed in all
40 60 80 100 120 140 160 180 200 2200
1
2
3
4
5
6
7
8x 10
4
RVS Score
No
. of S
ton
e B
uild
ing
s
BilaspurChambaHamirpurKangraKinnaurKulluLahulMandiShimlaSirmurSolanUna
Fig. 14 Normal distribution curve for stone masonry buildings
40 60 80 100 120 140 160 1800
2
4
6
8
10
x 104
RVS Score
No
. of
Ram
med
Ear
th B
uild
ing
s
ChambaHamirpurKangraKulluMandiSirmurSolanUna
Fig. 15 Normal distribution curve for rammed earth buildings
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districts. The mean and median of buildings range 110–130 and 105–135, respectively.
Around 5.3% of buildings in Sirmaur district and 2% of buildings in other districts will
have collapse stage. Buildings whose RVS score is less than or equal to 100 need to be
analyzed in detail. These analyses are beyond scope of the paper.
5 Conclusions
An attempt has been made to perform RVS of five varieties of buildings in Himachal
Pradesh state. RVS score are calculated for 9099 buildings and normal distribution curves
are plotted for each typology of building to understand the distribution of buildings in
60 70 80 90 100 110 120 130 1400
0.5
1
1.5
2
2.5x 10
4
RVS Score
No
. of
Hyb
rid
Bu
ildin
gs
BilaspurChambaHamirpurKangraKinnaurKulluLahulMandiShimlaSirmurSolanUna
Fig. 16 Normal distribution curve for hybrid buildings
40 60 80 100 120 140 160 180 2000
2
4
6
8
10
12
14
16
18x 10
4
RVS Score
No
. of
Bu
ildin
gs
RCBrickStoneRammed EarthHybrid
Fig. 17 Normal distribution curve as per building variety
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Himachal Pradesh state. In this study, a detailed analysis of RVS has been incorporated to
that of existing one. This RVS study enables us to calculate the risk by assessing the
structural vulnerability of different building typologies. It is observed that overall RVS
score for different building typologies range from 30 to 220. A statistical approach has
been considered to understand the building state using RVS scores. However, major
buildings turn out be in middle range of damage index and hence drawing meaningful
conclusion is a difficult task. However, there are low RVS score buildings which are
potentially vulnerable to future earthquakes. Also it is suggested that preliminary analysis
Table 2 Mean and standard deviation of buildings as per district wise and building variety wise
Name of District RC Brick masonry Stone masonry Rammed earth Hybrid
l r l r l r l r l r
Bilaspur 102.8 17.72 105.73 15.09 113.43 13.78 – – 106.45 7.7
Chamba 105 12.28 120.53 23.95 103.55 17.07 99.44 7.26 105.02 10.8
Hamirpur 110.4 17.7 118.08 17.95 113.03 15.81 111.88 14.19 108.25 6.41
Kangra 106.07 12.33 127.25 17.77 109.15 14.68 100.42 9.43 108.68 4.01
Kinnaur – – – – 99.75 7.42 – – 97.2 13.38
Kullu 105.84 9.71 129.16 13.53 110.90 13.91 106 11 106.95 6.93
Lahul Spiti 104.77 26.18 – – 91.88 17.28 – – 97.12 10.65
Mandi 107.23 15.30 108 20.28 101.9 19.5 96.6 15.43 105.53 10.61
Shimla 106.7 7.7 119.17 20.82 107.31 20.57 – – 103.86 11.86
Sirmur 104.27 13.85 120.42 21.41 115 21.68 102.5 9.57 100.12 12.59
Solan 101.87 16.5 104.75 20.74 105.45 24.95 99.21 19.43 102.73 10.53
Una 116.62 6.71 133.32 25.39 107.85 7.56 103 16.04 110.8 2.6
l mean, r standard deviation
Fig. 18 Classification of damage from normal distribution curve
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needs to be performed on few buildings and detailed analysis should be done for selected
buildings for calibrating RVS scores.
5.1 Recommendations
1. Implementation of the building code regulations for rammed earth, hybrid and stone
masonry buildings needs to be initiated in India.
2. Performance of the low-rise buildings constructed using locally available materials
must be improved. This factor could lead to a significant reduction of casualties in
future earthquakes.
3. Research is needed to investigate and improve the performance of the above buildings.
Acknowledgements The authors would like to express their gratitude to the TARU Leading Edge PrivateLimited, New Delhi. A special thanks goes to our colleagues Mr. Swajit Singh Goud, Mr. Gugan VigneshSelvaraj, Mr. Bodige Narender, Ms. Bhargavi Sattar, Mr. Ravikanth Chittiprolu, Mr. Pulkit Velani, Mr.Krishna Babu, and Mr. Raju Sangam in finalizing the buildings for preliminary and detailed analysis ofbuildings.
Table 3 State of damage and number of damage buildings of RC, brick, stone, rammed earth and hybridbuildings
State of damage Collapse Severe damage Moderate damage Slight damage No damage Total
RCC 32 210 1051 209 39 1541
BM 107 645 2984 546 81 4363
SM 38 179 948 148 28 1341
RE 11 86 341 71 9 518
Hybrid 32 193 902 167 25 1317
BilaspurChamba
HamirpurKangra
KinnaurKullu
LahulMandi
ShimlaSirmaur
607080
90100
110120130
140150
160170
180
0
100
200
300
400
500
DistrictsRVS Score
No
of
Bu
ildin
gs
Fig. 19 Distribution of number of buildings with respect to RVS score and each district of HP
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References
Ambraseys N, Bilham R (2000) A note on the Kangra Ms = 7.8 earthquake of 4 April 1905. Curr Sci79(1):45–50
Demartinos K, Dristos S (2006) First-level pre-earthquake assessment of buildings using fuzzy logic. EarthqSpectra 22:865–885
EERI Special Earthquake Report (2001) Preliminary observations on the origin and effects of the January26, 2001 Bhuj (Gujarat, India) Earthquake. California, USA
EERI Special Earthquake Report (2005) First report on the Kashmir Earthquake of October 8, 2005.California, USA
EERI Special Earthquake Report (2012) The Mw 6.9 Sikkim-Nepal Border Earthquake of September 18,2011. California, USA
FEMA 154 (1988) Rapid visual screening of buildings for potential seismic hazards—a handbook. FederalEmergency Management Agency, Washington
FEMA 178 (1989) NEHRP handbook for the seismic evaluation of existing buildings—a handbook. FederalEmergency Management Agency, Washington
FEMA 178 (1992) NEHRP handbook for the seismic evaluation of existing buildings—a handbook. FederalEmergency Management Agency, Washington
FEMA 310 (1998) Handbook for the seismic evaluation of buildings: a pre-standard—a handbook. FederalEmergency Management Agency, Washington
FEMA (1999) HAZUS: earthquake loss estimation methodology—a handbook. Federal Emergency Man-agement Agency, Washington D.C. Indian Standard Criteria for Ductile Detailing of RC StructuresSubjected to Seismic Forces, IS: 13920-2014, Bureau of Indian Standards, New Delhi
FEMA 154 (2002) Rapid visual screening of buildings for potential seismic hazards—a handbook. FederalEmergency Management Agency, Washington
Hassan AF, Sozen MA (1997) Seismic vulnerability assessment of low-rise buildings in regions withinfrequent earthquakes. ACI Struct J 94(1):31–39
HAZUS (2000) Estimated annualized earthquake losses for the United States, FEMA 366, Sept 2000IITK-GSDMA (2003) IITK-GSDMA guidelines for seismic evaluation and strengthening of buildings.
NICEE, KanpurJain CK (2006) Seismic vulnerability of buildings and population in India with a case study of Kanpur,
Master of Technology Dissertation, Department of Civil Engineering, Indian Institute of Technology,Kanpur
Jain SK, Mitra K, Manish K, Mehul S (2010) A proposed rapid visual screening procedure for seismicevaluation of RC-frame buildings in India. Earthq Spectra 26(3):709–729
JPDPA (2001) Seismic evaluation and retrofit. The Japan Building Disaster Prevention Association, TokyoKeya M (2008) Assessing urban fabric against natural disasters: a case study of seismic vulnerability of
Kolkata. Ph.D Thesis, Department of Architecture, Town and Regional Planning, Bengal Engineeringand Science University, Shibpur, India
Motamed H, Ashtiany MG (2012) An index for evaluating urban earthquake risk. In: Proceedings of theU.S-Iran seismic workshop, Tehran, Iran
Murty CVR, Goel RK, Goyal A, Jain SK, Sinha R, Durgesh CR, Jaswant NA, Rainer M (2002) Reinforcedconcrete structures. Earthq Spectra 18(S1):149–186
Narender B (2014) Development of a comprehensive seismic risk assessment model for built environment: acase study on Nanded-Waghala City, Maharashtra. Ph.D Thesis, Department of Civil Engineering,Earthquake Engineering Research Centre, International Institute of Information Technology,Hyderabad
Nateghi F (1998) Earthquakes, vulnerabilities and earthquake disaster management. IIEES Publications,Tehran
Nateghi F (2000) Seismic vulnerability of the Mega City of Tehran. In: Proceedings of 12th world con-ference on earthquake engineering, Auckland, New Zealand
National Disaster Management Authority of India (2007) National disaster management policy andguidelines—earthquakes
NRCC (1993) Manual for screening of buildings for seismic investigation by institute for research inconstruction. National Research Council Canada, Ottawa
NZSEE (2006) Assessment and improvement of the structural performance of buildings in earthquakes.Recommendations of a NZSEE Study Group on Earthquake Risk Buildings, June 2006, New Zealand
OASP (2000) Provisions for pre-earthquake vulnerability assessment of public buildings (Part A). GreekEarthquake Planning and Protection Organization, Athens
Nat Hazards
123
Ozcebe G, Sucuoglu H, Yucemen MS, Yakut A, Kubin J (2006) Seismic risk assessment of existing buildingstock in Istanbul, a pilot application in Zeytinburnu District. In: Proceedings of 8th US nationalconference on earthquake engineering, San Fransisco
Ozdemir R, Taskin B (2006) Seismic safety screening method for Istanbul Metropolitan City. In: Pro-ceedings of 10th international East Asia Pacific conference on structural engineering and construction,Bangkok, Thailand
Pradeep KR, Murty CVR (2014) Earthquake safety of houses in India: understanding the bottlenecks inimplementation. Indian Concr J 88(9):51–63
Sen Z (2010) Rapid visual earthquake hazard evaluation of existing buildings by fuzzy logic modeling.Expert Syst Appl 37(8):5653–5660
SIA-2018 (2004) Assessment of existing buildings with respect to earthquakes (in German). Technical note2018. Swiss Society of Civil Engineers and Architects, Zurich, Switzerland
Singh P (2005) Population vulnerability for earthquake loss estimation using community based approachwith GIS: urban infrastructure management. Master of Science Thesis, International Institute for GeoInformation Science and Earth Observation, Netherlands
Sinha R, Goyal A (2004) A national policy for seismic vulnerability assessment of buildings and procedurefor rapid visual screening of buildings for potential seismic vulnerability. Department of Civil Engi-neering, Indian Institute of Technology Bombay, Bombay
Srikanth T, Pradeep KR (2010) Rapid visual survey of existing buildings in Gandhidham and Adipur Cities,Kachchh, Gujarat. In: Proceedings of international symposium on the 2001 Bhuj earthquake andadvances in earth sciences and engineering, Gujarat, India
Srikanth T, Pradeep KR, Ajay PS, Rastogi BK, Santosh K (2010) Earthquake vulnerability assessment ofexisting buildings in Gandhidham and Adipur Cities, Kachchh, Gujarat (India). Eur J Sci Res41(3):336–353
Sucuoglu H, Yazgan U, Yakut A (2007) A screening procedure for seismic risk assessment in urban buildingstocks. Earthq Spectra 23(2):441–458
Nat Hazards
123
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